The "problem" you're observing is because of the **very nature** of floating point arithmetic.

In FP the precision depends on the scale; around the value `1.0`

the precision is not enough to be able to differentiate between `1.0`

and `1.0+min_representable`

where `min_representable`

is the smallest possible value greater than zero (even if we only consider the smallest normalized number, `std::numeric_limits<float>::min()`

... the smallest denormal is another few orders of magnitude smaller).

For example with double-precision 64-bit IEEE754 floating point numbers, around the scale of `x=10000000000000000`

(10^{16}) it's impossible to distinguish between `x`

and `x+1`

.

The fact that the resolution changes with scale is the very reason for the name "floating point", because the decimal point "floats". A fixed point representation instead will have a fixed resolution (for example with 16 binary digits below units you have a precision of 1/65536 ~ 0.00001).

For example in the IEEE754 32-bit floating point format there is one bit for the sign, 8 bits for the exponent and 31 bits for the mantissa:

The smallest value `eps`

such that `1.0f + eps != 1.0f`

is available as a pre-defined constant as `FLT_EPSILON`

, or `std::numeric_limits<float>::epsilon`

. See also machine epsilon on Wikipedia, which discusses how epsilon relates to rounding errors.

I.e. epsilon is the smallest value that does what you were expecting here, making a difference when added to 1.0.

The more general version of this (for numbers other than 1.0) is called 1 unit in the last place (of the mantissa). See Wikipedia's ULP article.

`float`

is 38 orders of magnitude smaller than 1, at 1.175e-38. The`float`

type only provides six digits of precision, so adding that minimum value to 1 is tantamount to adding zero. – bwDraco Dec 25 '16 at 3:15